dc.identifier.uri |
http://dx.doi.org/10.15488/16715 |
|
dc.identifier.uri |
https://www.repo.uni-hannover.de/handle/123456789/16842 |
|
dc.contributor.author |
Bailes, M.
|
|
dc.contributor.author |
Berger, B.K.
|
|
dc.contributor.author |
Brady, P.R.
|
|
dc.contributor.author |
Branchesi, M.
|
|
dc.contributor.author |
Danzmann, K.
|
|
dc.contributor.author |
Evans, M.
|
|
dc.contributor.author |
Holley-Bockelmann, K.
|
|
dc.contributor.author |
Iyer, B.R.
|
|
dc.contributor.author |
Kajita, T.
|
|
dc.contributor.author |
Katsanevas, S.
|
|
dc.contributor.author |
Kramer, M.
|
|
dc.contributor.author |
Lazzarini, A.
|
|
dc.contributor.author |
Lehner, L.
|
|
dc.contributor.author |
Losurdo, G.
|
|
dc.contributor.author |
Lück, H.
|
|
dc.contributor.author |
McClelland, D.E.
|
|
dc.contributor.author |
McLaughlin, M.A.
|
|
dc.contributor.author |
Punturo, M.
|
|
dc.contributor.author |
Ransom, S.
|
|
dc.contributor.author |
Raychaudhury, S.
|
|
dc.contributor.author |
Reitze, D.H.
|
|
dc.contributor.author |
Ricci, F.
|
|
dc.contributor.author |
Rowan, S.
|
|
dc.contributor.author |
Saito, Y.
|
|
dc.contributor.author |
Sanders, G.H.
|
|
dc.contributor.author |
Sathyaprakash, B.S.
|
|
dc.contributor.author |
Schutz, B.F.
|
|
dc.contributor.author |
Sesana, A.
|
|
dc.contributor.author |
Shinkai, H.
|
|
dc.contributor.author |
Siemens, X.
|
|
dc.contributor.author |
Shoemaker, D.H.
|
|
dc.contributor.author |
Thorpe, J.
|
|
dc.contributor.author |
van den Brand, J.F.J.
|
|
dc.contributor.author |
Vitale, S.
|
|
dc.date.accessioned |
2024-03-21T10:56:54Z |
|
dc.date.available |
2024-03-21T10:56:54Z |
|
dc.date.issued |
2021 |
|
dc.identifier.citation |
Bailes, M.; Berger, B.K.; Brady, P.R.; Branchesi, M.; Danzmann, K. et al.: Gravitational-wave physics and astronomy in the 2020s and 2030s. In: Nature Reviews Physics 3 (2021), Nr. 5, S. 344-366. DOI: https://doi.org/10.1038/s42254-021-00303-8 |
|
dc.description.abstract |
The 100 years since the publication of Albert Einstein’s theory of general relativity saw significant development of the understanding of the theory, the identification of potential astrophysical sources of sufficiently strong gravitational waves and development of key technologies for gravitational-wave detectors. In 2015, the first gravitational-wave signals were detected by the two US Advanced LIGO instruments. In 2017, Advanced LIGO and the European Advanced Virgo detectors pinpointed a binary neutron star coalescence that was also seen across the electromagnetic spectrum. The field of gravitational-wave astronomy is just starting, and this Roadmap of future developments surveys the potential for growth in bandwidth and sensitivity of future gravitational-wave detectors, and discusses the science results anticipated to come from upcoming instruments. |
eng |
dc.language.iso |
eng |
|
dc.publisher |
London : Springer Nature |
|
dc.relation.ispartofseries |
Nature Reviews Physics 3 (2021), Nr. 5 |
|
dc.rights |
CC BY 3.0 Unported |
|
dc.rights.uri |
https://creativecommons.org/licenses/by/3.0/ |
|
dc.subject |
Gravitational effects |
eng |
dc.subject |
Relativity |
eng |
dc.subject |
Signal detection |
eng |
dc.subject |
Albert Einstein |
eng |
dc.subject |
Astrophysical sources |
eng |
dc.subject |
Binary neutron stars |
eng |
dc.subject |
Electromagnetic spectra |
eng |
dc.subject |
General Relativity |
eng |
dc.subject |
Gravitational wave detectors |
eng |
dc.subject |
Gravitational-wave signals |
eng |
dc.subject |
Key technologies |
eng |
dc.subject |
Gravity waves |
eng |
dc.subject.ddc |
530 | Physik
|
|
dc.title |
Gravitational-wave physics and astronomy in the 2020s and 2030s |
eng |
dc.type |
Article |
|
dc.type |
Text |
|
dc.relation.essn |
2522-5820 |
|
dc.relation.doi |
https://doi.org/10.1038/s42254-021-00303-8 |
|
dc.bibliographicCitation.issue |
5 |
|
dc.bibliographicCitation.volume |
3 |
|
dc.bibliographicCitation.firstPage |
344 |
|
dc.bibliographicCitation.lastPage |
366 |
|
dc.description.version |
publishedVersion |
eng |
tib.accessRights |
frei zug�nglich |
|